The present invention relates generally to optical transceivers, and more particularly to optical arrangements for components of optical transceivers.
Optical communication systems can generally support high data rates, and do so with lower power consumption and with reduced signal loss or interference over appreciable distances, compared to for example electrical signal paths of similar length. For these reasons, and others, optical transceivers coupled to optical fibers have long been used for long-haul communication systems.
For shorter distance communication, for example in data center environments, optical communication systems are also increasingly being used. In data center environments, however, space may be at a premium. Accordingly, use of co-packaged high density modules that provide multiple lanes of communication may be desired.
Photonic integrated circuits (PICs) may be used in such modules, whether transceiver modules or other modules. PICs may include a laser for providing light to carry a data signal, and, for example, a waveguide to carry the light to an edge of the PIC. The waveguide may include an angle, changing direction of the waveguide, as it approaches an edge, or facet, of the PIC chip. This waveguide angled facet may be useful in reducing reflections back towards the laser or other optical component. Unfortunately, the waveguide angle facet also results in light from the waveguide not exiting the PIC chip at an angle normal to the PIC chip, which may cause problems in coupling light from the PIC chip to other optical components, for example particularly doing so without undue loss of optical power. These problems may be exacerbated when the PIC chip includes arrays of lasers with corresponding arrays of waveguides.
Some embodiments in accordance with aspects of the invention provide an optical module including a Phototonic Integrated Circuit (PIC), an output medium, and an optical coupler. The PIC may have an array of waveguides. Each of the waveguides emits light emits light having an angle of incidence that is non-zero and has an angle facet that is non-normal with respect to an output edge of the PLC. The optical coupler may include one or more optical elements for coupling light from the waveguides of the PIC to the output medium. Each of the optical elements may focus light from one of the waveguides at a focal length that is the same as a focal length of the other optical elements. Furthermore, each of the optical elements may have unique optical properties determined by a device distance between the optical element and the associated waveguide.
In accordance with some embodiments, the optical coupler may include a first lens array. Each lens in the first lens array may focuses the light from one of the waveguides of the PIC and has a radius of curvature that is based upon the focal length of the lens and a device distance of the waveguide emitting the light focused by the lens. In accordance with many of these embodiments, the optical coupler may include a step index box made of material that causes the light emitted from each of the waveguides to have the same effective device distance and each lens in the first lens array has the same radius of curvature based on the light emitted from the waveguides having the same effective device distance.
In accordance with some embodiments, the optical coupler includes a plurality of collimating lenses wherein each of the plurality of collimating lenses collimates light from one of the waveguides of the PIC into one lens of the first lens array and each lens of the first lens array focus the collimated light onto a single portion of the output medium.
In accordance with a number of these embodiments, the optical coupler may also include a second lens array. Each lens in the first lens array focuses light onto one lens of the second lens array and each lens of the second lens array focuses light on a particular portion of the output medium.
In some of these embodiments, each lens of the first lens array collimates light from one of the waveguides onto one lens of the second lens array and each lens of the second lens array focuses the collimated light onto a particular portion of the output medium. In some of these embodiments, each lens in the first lens array may be a glass ball lens and each lens in the second lens array may be a glass ball lens. In accordance with some other embodiments, each lens in the first lens array may be a silicon ball lens and each lens in the second lens array may be a glass ball lens. In a number of these embodiments, at least one lens in the first lens array and/or the second lens array is mounted on a moveable MEMs platform.
In accordance with many embodiments, the optical coupler may include an isolator between the PIC and the output medium. In accordance with a few embodiments, the optical elements are portions of a larger full lens.
In accordance with some embodiments, the output medium may include one or more optic fibers. In accordance with some other embodiments, the output medium is a planar lightwave circuit (PLC). In accordance with some of these embodiments, he PIC and the PLC are offset from one another such that exit directions of light from the waveguides of the PIC approach entrance directions of light into waveguides of the PLC. In accordance with a few of these embodiments, the PIC is at an angle with respect to the optical coupler such that the light emitted by the waveguides of the PIC is at a non-normal angle to a front facet edge of the PIC and arrives at the optical coupler at a non-normal angle.
Some embodiments in accordance with aspects of the invention provide an optical module having an array of waveguides, each with angle facets, and a planar lightwave circuit (PLC), with an optical coupler coupling light from the PIC to the PLC, with an edge of the PIC at an angle to a closest edge of the PLC, and the optical coupler including a plurality of elements, which may be lenses, each with a different optical property.
In some such embodiments outputs of the different PIC waveguides are at different distances to the optical coupler, and inputs of the PLC are at the same distance to the optical coupler. In some such embodiments the plurality of lenses have an aspheric output surface, each with a different radius of curvature. In some such embodiments the radius of curvature of each of the lenses is such that the focal length of each lens, in view of the varying distances to the waveguide outputs, is the same.
In some embodiments a step index block is interposed between the PIC and the optical coupler. In some embodiments the step index block serves to provide a common distance for free-space propagation of light from the waveguides of the PIC.
In some embodiments the lenses are mounted on a MEMs structure, allowing for correction of misalignment of the PIC and PLC.
These and other aspects and embodiments of the invention are more fully comprehended upon review of this disclosure.
In the embodiment of
The optical elements of the optics 113 vary so as to focus light from each of the waveguides of the PIC 111 to corresponding waveguides of the PLC 115. In some embodiments, the optical elements 113 have varying optical properties. In some embodiments, the optical elements 113 have optical properties that vary such that different ones of the optical elements focus images at the same image distance despite different object distances for the different ones of the optical elements 113. In some embodiments, the optical elements 113 are arranged in a linear array, with successive optical elements in the linear array having an output surface, with the output surface of each successive optical element having a different radius of curvature. In some embodiments the output surfaces are aspheric. In some embodiments, the optical elements 113 are lenses. In some embodiments the lenses have an aspheric output surface, with at least some of the lenses having different radius of curvature for the aspheric output surface. In some embodiments, the lenses (or array of lenses) are mounted on a moveable MEMs platform, to allow for positioning of the lenses to focus light from the PIC 111 into waveguides of the PLC 115. In some embodiments, the moveable MEMs platform is as discussed in U.S. Pat. No. 8,346,037 entitled “MICROMECHANICALLY ALIGNED OPTICAL ASSEMBLY” or U.S. Pat. No. 8,917,963, entitled “MEMS-BASED LEVERS AND THEIR USE FOR ALIGNMENT OF OPTICAL ELEMENTS” the disclosures of which are incorporated by reference.
For the PIC 211, the waveguides may be used, for example, for passing light from a laser or other light source (not shown in
The angle facet, however, results in the waveguide 213 being at an angle non-normal to the output edge of the PLC 211, with the angle being shown as θ1 in
The PIC 311 includes a plurality of light sources, for example lasers, to provide light to be passed out of the PIC 311 through a plurality of waveguides, for example waveguide 319. The waveguides include angle facets, for example angle facet 321, near an output edge 323 of the PIC 311. The angle facets have an angle θ1, with respect to the waveguides, which are perpendicular to the output edge 323 of the PIC 311. Due to refraction, light exiting the waveguides will do so at an angle θ2 with respect to a normal to the output edge of the PLC 317.
For example to reduce the angle at which the light approaches the lens array 313, the PIC 311 in the embodiment of
The lens array 313 focuses the light from the PIC 311 into waveguides of the PLC 317. Preferably the lenses of the lens array 313 does so to maximize power into the waveguides of the PLC 317. In some embodiments, depending on the relative angle of approach of light from the PIC 311, and, in some embodiments, position of the PLC 317, lenses of the lens array 313 may be aspheric. In addition, for the lens array 313, although the image distance is generally the same for each lens, as each of the lenses are generally the same distance to the PLC 311. The object distance, however, differs for each lens, considering that the distance from the output edge 323 of the PIC 311 to the lens array varies. Accordingly, the focal length of the lenses also varies. In
The embodiment of
The refractive index of the materials may be set such that the effective optical distance between the PIC 311 and the lens array 413 is a constant. In such embodiments, lenses of the lens array 413 may have the same focal length, and may for example have the same radius of curvature. Alternatively, in some embodiments the refractive index of various portions of the step index block 415 may vary, but not sufficiently so as to allow for lenses of the lens array 413 to have the same radius of curvature.
The lens array 513 focuses light from each of the waveguides of the PIC 311 into corresponding waveguides of the PLC 317. To do so, considering the different optical distances between the different PIC waveguide-lens pairs, the lenses generally have different radii of curvature.
In addition, in some embodiments, and for example as shown in
In
Light from waveguides of the PIC 311 are collimated by lenses of a lens array 713. In many embodiments the lenses are portions of a larger full lens. The collimated light is passed through one or more optical isolators 715, and focused by further lenses 717 into an output medium. In
In some embodiments, and as illustrated in
Light from the waveguides of the PIC 311 is passed through an array of lenses 913. The array of lenses 913 includes bi-concave lens for focusing light into waveguides of a PLC 317. In most embodiments the lenses, or the input or output lenses, are aspheric, to account for the angle at which light reaches the lenses from the angled facet waveguides of the PIC 311. As with several other embodiments, an optical isolator 315 is between the array of lenses 913 and the PLC 317.
A first lens array 1014 directs light from the PIC 1013 towards a second lens array 1025. The second lens array 1025 directs light into waveguides of the PLC 1019. In some embodiments the first lens array 1014 includes a plurality of glass ball lenses, for example glass ball lens 1015. In some embodiments the second lens array 1025 also includes a plurality of glass ball lenses, for example, glass ball lens 1027. An optical isolator 1017 is between the two lens arrays.
Also in the embodiment of
A first lens array 1114 directs light from the PIC 1113 towards a second lens array 1125. The second lens array 1125 directs light into waveguides of the PLC 1119. An optical isolator 1117 is between the two lens arrays. In the embodiment of
Although the invention has been discussed with respect to various embodiments, it should be recognized that the invention comprises the novel and non-obvious claims supported by this disclosure.
This invention claims priority to U.S. Provisional Patent Application 62/421,966 entitled “Transceiver High Density Module” filed on Nov. 14, 2016, that is hereby incorporated by reference in its entirety as if set forth herewith.
Number | Date | Country | |
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62421966 | Nov 2016 | US |
Number | Date | Country | |
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Parent | 15812273 | Nov 2017 | US |
Child | 16688895 | US |